# How to automatically set ylim from data shown on the screen after setting xlim

For example, after I set xlim, the ylim is wider than the range of data points shown on the screen. Of course, I can manually pick a range and set it, but I would prefer if it is done automatically.

Or, at least, how can we determine y-range of data points shown on screen?

plot right after I set xlim:

plot after I manually set ylim:

-

This approach will work in case `y(x)` is non-linear. Given the arrays `x` and `y` that you want to plot:

``````lims = gca().get_xlim()
i = np.where( (x > lims[0]) &  (x < lims[1]) )[0]
gca().set_ylim( y[i].min(), y[i].max() )
show()
``````
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Thanks Saullo, however, autoscale(axis='y') still calculates the data range from the full data set, including data points not shown on the screen –  Liang Aug 11 '13 at 15:17
Thank you for the feedback.. I've updated the answer for a case where `y(x)` is non-linear... –  Saullo Castro Aug 11 '13 at 22:22

To determine the y range you can use

``````ax = plt.subplot(111)
ax.plot(x, y)
y_lims = ax.get_ylim()
``````

which will return a tuple of the current y limits.

It seems however that you will probably need to automate setting the y limits by finding the value of y data at at your x limits. There are many ways to do this, my suggestion would be this:

``````import matplotlib.pylab as plt
ax = plt.subplot(111)
x = plt.linspace(0, 10, 1000)
y = 0.5 * x
ax.plot(x, y)
x_lims = (2, 4)
ax.set_xlim(x_lims)

# Manually find y minimum at x_lims[0]
y_low = y[find_nearest(x, x_lims[0])]
y_high = y[find_nearest(x, x_lims[1])]
ax.set_ylim(y_low, y_high)
``````

where the function is with credit to unutbu in this post

``````import numpy as np
def find_nearest(array,value):
idx = (np.abs(array-value)).argmin()
return idx
``````

This however will have issues when the data y data is not linear.

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To me, your answer is the least confusing way. But there could be a quick improvement, that we may find y_low and y_high by taking the min and max between y[find_nearest(x, x_lims[0])] and y[find_nearest(x, x_lims[1])], that is: `y_low = y[find_nearest(x, x_lims[0]):find_nearest(x, x_lims[1])].min() y_high = y[find_nearest(x, x_lims[0]):find_nearest(x, x_lims[1])].max()`. –  Liang Aug 11 '13 at 22:01